1 / 36

Hodgkin & Huxley II. Voltage Clamp

Hodgkin & Huxley II. Voltage Clamp. MK Mathew NCBS, TIFR UAS – GKVK Campus Bangalore. IBRO Course in Neuroscience Center for Cognitive N euroscience & Semantics, University of L atvia Riga, L atvia August 21-August 29, 2013.

betty
Download Presentation

Hodgkin & Huxley II. Voltage Clamp

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Hodgkin & Huxley II. Voltage Clamp MK Mathew NCBS, TIFR UAS – GKVK Campus Bangalore IBRO Course in Neuroscience Center for Cognitive Neuroscience & Semantics, University of Latvia Riga, Latvia August 21-August 29, 2013

  2. Voltage clamp of the squid axon. Vi is the internal potential measured with a pipette inserted in the axon. Ve is the external potential measured by an external electrode. Vm=Vi-Ve as computed by amplifier A1. A2 compares Vm with Vc (which is the command desired voltage) to inject current I, which maintains Vm at Vc. The current injected by the axial wire crosses the axonal membrane as it is drained by the chamber plates and measured by a current measuring device. Bezanilla web page

  3. Voltage Clamp currents in a Squid Axon. An axon is bathed in sea water and voltage clamped by the axial wire method. The membrane potential is held at -65 mV and then hyperpolarized in a step to -130 mV or depolarized in a step to 0 mV. Outward ionic current is shown as an upward deflection. The membrane permeability mechanisms are clearly asymmetrical. Hyperpolarization produces only a small inward current, whereas depolarization elicits a larger biphasic current. T = 3.8oC Nicholls “From Neuron to Brain”

  4. IK = gK (Em – EK) Nicholls “From Neuron to Brain”

  5. IK(t)= gK(t).(Em(t)– EK) Nicholls “From Neuron to Brain”

  6. INa=gNa(Em – ENa) 2 terms: Rising phase and falling phase Nicholls “From Neuron to Brain”

  7. Steady State (Plateau) Value of IK Peak INa Reversal Potential

  8. Nicholls: Neuron to Brain

  9. C O G/Gmax V1/2

  10. Fits to n4

  11. Limiting value gK Fits to n4

  12. K+ CHANNEL Putting n4 and the voltage dependence together: Let the probability of a gating particle being ON be n ON OFF Each of 4 gating particles can be either ON or OFF (Protein 3D Configurations) Channel is open when all 4 Gating Particles are ON Probability of the channel being OPEN is then n4

  13. The Potassium Channel • The probability of a Gating Particle being ON: • The probability of the channel being open: • The conductance of a patch of membrane to K+ when all channels are open: (Constant obtained by experiments) • The conductance of a patch of membrane to K+ when the probability of a subunit being open is n:

  14. INa=gNa(Em – ENa) 2 terms: Rising phase and falling phase Nicholls “From Neuron to Brain”

  15. Na+ CHANNEL Na channel also has 4 sensors or gating particles 3 of these particles are involved in the CLOSED to OPEN transition m 1 of these particles is involved in INACTIVATION h Na m (Protein 3D Configurations) h Probability of C O gating particle being ON = m Probability of Channel being OPEN = m3 Probability of INACTIVATION particle being OFF = h Probability of Channel being CONDUCTING = m3h

  16. The Sodium Channel (2) • The probability of a fast subunit being open: • The probability of a slow subunit being open: • The probability of the channel being open: • The conductance of a patch of membrane to Na+ when all channels are open: (Constant obtained by experiments) • The conductance of a patch of membrane to Na+ :

  17. The Full Hodgkin-Huxley Model

  18. C O Resting Potential

  19. 1 . 0 e c n 0 . 8 a t c u 0 . 6 d n o C 0 . 4 m u D e p o l a r i z e t h e i d 0 . 2 o C e l l S 0 . 0 - 8 0 - 6 0 - 4 0 - 2 0 0 2 0 P o t e n t i a l ( m V ) O p e n S o d i u m C h a n n e l s

  20. V(x) = Vo e-x/l rm/rax l

  21. m m

  22. The capacitance of the surface of a myelinated axon is about 1000 times smaller than that of an unmyelinated neuron the conductance of the membrane to Na+ and K+ is also decreased, which has the effect of increasing the space constant for passive spread from Molecules of Life

  23. Amplification Saltatory conduction Myelination Passive propagation Ri: Unaffected Rm: Increased (series resistors) Transient conductance is better: Cm: decreased (series capacitors Metabolism is lower: No ion channels except at nodes

  24. Nicholls “From Neuron to Brain”

More Related